起爆理论与技术（英文版）（Initiation Theory and Technology）

作者: 严楠著

出版社: 北京理工大学出版社

出版时间: 2007-05

版次: 1

ISBN: 9787564012571

定价: 32.00

装帧: 平装

开本: 其他

纸张: 胶版纸

分类: 工程技术

5人买过

《起爆理论与技术（英文版）（InitiationTheoryandTechnology）》是关于含能材料起爆技术的英文版读物，主要介绍炸药、火药、烟火药的起爆理论与技术，包括将各种不同刺激能量形式如机械能、电能、光能、冲击波能、热能等转换成点火或起爆的换能技术，以及各种换能系统的组成、结构、作用原理和设计考虑的起爆应用技术。本书可作为相关专业的本科生和研究生的专业英语教材及双语教学教材。 Chapter 1 Initiation by Heat

1.1 Concept and Classification

1.2 Thermal Ignition Theory

1.2.1 Ignition Theory in Solid

1.2.2 Ignition Theory in Gas

1.2.3 Ignition Theory in Heterogeneous Phase

1.3 Application of Initiation by Heat

1.3.1 Flame or Spark Initiato

1.3.2 Output of Prime

1.3.3 Hot Bridgewire Initiato

Exercises

Chapter 2 Initiation by Mechanical Stimuli

2.1 Concept and Classification

2.2 Initiation Mechanism

2.2.1 Initiation by Impact or by Percussion

2.2.2 Initiation by Friction

2.2.3 Initiation by Stab

2.3 Application of Mechanical Initiation

2.3.1 Percussion Initiato

2.3.2 Stab Primer or Stab Detonator

2.3.3 Energy-Power Relatiohip

Exercises

Chapter 3 Electric Initiation or Initiation by Electric Power

3.1 Concept and Classification

3.2 Initiation Mechanism

3.2.1 Electrothermal Initiation

3.2.2 Electric Spark Initiation

3.2.3 Conductive Mixture Electric Initiation

3.2.4 Electrical But Initiation

3.3 Application of Electrical Initiation

3.3.1 Hot Bridgewire Electric Initiato

3.3.2 Electric Spark Gap Detonator

3.3.3 Conductive Mixture Electric Detonator

3.3.4 Other Electric Initiato

Exercises

Chapter 4 Laser Initiation Theory

4.1 Concept and Classification

4.1.1 Concept of Laser Initiation

4.1.2 Background for Laser Initiation

4.1.3 Advantages of Laser Initiation Systems

4.2 Laser Ignition Energy Traform Mechanism of Energetic Materials

4.2.1 Laser Ignition of Explosive

4.2.2 Laser Ignition of Pyrotechnics

4.2.3 Pyrotechnic Laser Ignition System Design

4.2.4 Mechanisms for Laser Ignition of Pyrotechnics

4.3 Application Technology

4.3.1 Literature Review

4.3.2 Laser Diode Ignition

4.3.3 Laser Detonator

4.3.4 Laser Ignited Actuator

Exercises

Chapter 5 Flayer Initiation Theory

5.1 Concept and Classification

5.2 Acceleration Theory of Fragments

5.2.1 Gurney Flayer Acceleration Model

5.2.2 Effective Charge in Gumey Model

5.2.3 Flyer Impulse Estimation

5.2.4 Gurney Data for Explosives

5.2.5 Accelerated Flyer Electric Gumey by Electric But

5.2.6 Flyer Initiation Criterion

Exercises

Chapter 6 Initiation Theory by Shock

6.1 Concept and Classification r

6.1.1 Shock

6.1.2 Deflagration

6.1.3 Detonation

6.2 - Initiation Theory

6.2.1 Shock Theory

6.2.2 Detonation Waves

6.2.3 Traition from Deflagration to Detonation

6.2.4 Actual Detonation

Exercises

Chapter 7 Exploding Bridgewire and Exploding Foil Initiation Theory

7.1 Concept and Classification

7.1.1 Exploding Bridgewire （EBW） Detonator

7.1.2 Exploding Foil Initiato （EFI）

7.2 Electric But Characteristics of EBWs

7.2.1 Explosion of the Bridgewire

7.2.2 Detonation of Initial Pressing

7.2.3 Effects of Cables

7.2.4 Function Time of EBWs

7.3 Electric But Characteristics of EFIs

7.3.1 Electric But Characteristics of EFIs

7.3.2 Flyer Acceleration Characteristics in Electric But Process

7.4 Application Technology

7.4.1 Typical Chip Slapper Detonator Design

7.4.2 New Slapper Design

7.4.3 Typical EFI Igniter Design

7.4.4 A Typical EFI Ignition System

Exercises

Chapter 8 Semiconductor Bridge Initiation Theory

8.1 Concept and Classification

8.1.1 Concept

8.1.2 Classification

8.1.3 Brief Description of SCB Technique Development

8.1.4 SCB Production Process

8.2 General Initiation Mechanism

8.2.1 SCB Ignition Features in Comparison with HBW

8.2.2 Characteristics of Electric But Process

8.2.3 Characteristics of Electrothermal Performance

8.2.4 Interface Design of the SCB with Energetic Material

8.3 SCB Ignition Features of Different Energetic Material

8.4 Characteristics of SCB Plasma

8.4.1 Experimental Arrangement

8.4.2 SCB Phase Traition Observed

8.4.3 Temporal Evolution of SCB Plasma Appearance and Emission Inteity

8.4.4 SCB Plasma Fluid Characteristics

8.4.5 SCB Plasma Temperature Characteristics

8.5 Comparison of Plasma Generation Behavio Between Single-SCB

and Poly-SCB

8.5.1 Experimentation

8.5.2 Comparison of Electrical But Characteristics Between Two-type

SCB Devices

8.5.3 Finite Element Analysis for Heating of Two-type SCB Devices

8.5.4 Theoretical Modeling for Thermal Structures of Two-type SCB Devices

8.6 Reactive SCB--A New Technique

8.6.1 Challenge Agait the Conventional SCB

8.6.2 Reactive SCB Technology

8.7 Next Generation SCB Initiato

Exercises

References
内容简介:
《起爆理论与技术（英文版）（InitiationTheoryandTechnology）》是关于含能材料起爆技术的英文版读物，主要介绍炸药、火药、烟火药的起爆理论与技术，包括将各种不同刺激能量形式如机械能、电能、光能、冲击波能、热能等转换成点火或起爆的换能技术，以及各种换能系统的组成、结构、作用原理和设计考虑的起爆应用技术。本书可作为相关专业的本科生和研究生的专业英语教材及双语教学教材。
目录:
Chapter 1 Initiation by Heat

1.1 Concept and Classification

1.2 Thermal Ignition Theory

1.2.1 Ignition Theory in Solid

1.2.2 Ignition Theory in Gas

1.2.3 Ignition Theory in Heterogeneous Phase

1.3 Application of Initiation by Heat

1.3.1 Flame or Spark Initiato

1.3.2 Output of Prime

1.3.3 Hot Bridgewire Initiato

Exercises

Chapter 2 Initiation by Mechanical Stimuli

2.1 Concept and Classification

2.2 Initiation Mechanism

2.2.1 Initiation by Impact or by Percussion

2.2.2 Initiation by Friction

2.2.3 Initiation by Stab

2.3 Application of Mechanical Initiation

2.3.1 Percussion Initiato

2.3.2 Stab Primer or Stab Detonator

2.3.3 Energy-Power Relatiohip

Exercises

Chapter 3 Electric Initiation or Initiation by Electric Power

3.1 Concept and Classification

3.2 Initiation Mechanism

3.2.1 Electrothermal Initiation

3.2.2 Electric Spark Initiation

3.2.3 Conductive Mixture Electric Initiation

3.2.4 Electrical But Initiation

3.3 Application of Electrical Initiation

3.3.1 Hot Bridgewire Electric Initiato

3.3.2 Electric Spark Gap Detonator

3.3.3 Conductive Mixture Electric Detonator

3.3.4 Other Electric Initiato

Exercises

Chapter 4 Laser Initiation Theory

4.1 Concept and Classification

4.1.1 Concept of Laser Initiation

4.1.2 Background for Laser Initiation

4.1.3 Advantages of Laser Initiation Systems

4.2 Laser Ignition Energy Traform Mechanism of Energetic Materials

4.2.1 Laser Ignition of Explosive

4.2.2 Laser Ignition of Pyrotechnics

4.2.3 Pyrotechnic Laser Ignition System Design

4.2.4 Mechanisms for Laser Ignition of Pyrotechnics

4.3 Application Technology

4.3.1 Literature Review

4.3.2 Laser Diode Ignition

4.3.3 Laser Detonator

4.3.4 Laser Ignited Actuator

Exercises

Chapter 5 Flayer Initiation Theory

5.1 Concept and Classification

5.2 Acceleration Theory of Fragments

5.2.1 Gurney Flayer Acceleration Model

5.2.2 Effective Charge in Gumey Model

5.2.3 Flyer Impulse Estimation

5.2.4 Gurney Data for Explosives

5.2.5 Accelerated Flyer Electric Gumey by Electric But

5.2.6 Flyer Initiation Criterion

Exercises

Chapter 6 Initiation Theory by Shock

6.1 Concept and Classification r

6.1.1 Shock

6.1.2 Deflagration

6.1.3 Detonation

6.2 - Initiation Theory

6.2.1 Shock Theory

6.2.2 Detonation Waves

6.2.3 Traition from Deflagration to Detonation

6.2.4 Actual Detonation

Exercises

Chapter 7 Exploding Bridgewire and Exploding Foil Initiation Theory

7.1 Concept and Classification

7.1.1 Exploding Bridgewire （EBW） Detonator

7.1.2 Exploding Foil Initiato （EFI）

7.2 Electric But Characteristics of EBWs

7.2.1 Explosion of the Bridgewire

7.2.2 Detonation of Initial Pressing

7.2.3 Effects of Cables

7.2.4 Function Time of EBWs

7.3 Electric But Characteristics of EFIs

7.3.1 Electric But Characteristics of EFIs

7.3.2 Flyer Acceleration Characteristics in Electric But Process

7.4 Application Technology

7.4.1 Typical Chip Slapper Detonator Design

7.4.2 New Slapper Design

7.4.3 Typical EFI Igniter Design

7.4.4 A Typical EFI Ignition System

Exercises

Chapter 8 Semiconductor Bridge Initiation Theory

8.1 Concept and Classification

8.1.1 Concept

8.1.2 Classification

8.1.3 Brief Description of SCB Technique Development

8.1.4 SCB Production Process

8.2 General Initiation Mechanism

8.2.1 SCB Ignition Features in Comparison with HBW

8.2.2 Characteristics of Electric But Process

8.2.3 Characteristics of Electrothermal Performance

8.2.4 Interface Design of the SCB with Energetic Material

8.3 SCB Ignition Features of Different Energetic Material

8.4 Characteristics of SCB Plasma

8.4.1 Experimental Arrangement

8.4.2 SCB Phase Traition Observed

8.4.3 Temporal Evolution of SCB Plasma Appearance and Emission Inteity

8.4.4 SCB Plasma Fluid Characteristics

8.4.5 SCB Plasma Temperature Characteristics

8.5 Comparison of Plasma Generation Behavio Between Single-SCB

and Poly-SCB

8.5.1 Experimentation

8.5.2 Comparison of Electrical But Characteristics Between Two-type

SCB Devices

8.5.3 Finite Element Analysis for Heating of Two-type SCB Devices

8.5.4 Theoretical Modeling for Thermal Structures of Two-type SCB Devices

8.6 Reactive SCB--A New Technique

8.6.1 Challenge Agait the Conventional SCB

8.6.2 Reactive SCB Technology

8.7 Next Generation SCB Initiato

Exercises

References

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起爆理论与技术（英文版）（Initiation Theory and Technology）

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